JPH046335A - Humidifier - Google Patents

Abstract

PURPOSE:To restrict any influence of humidifying water against a heat exchanger by a method wherein a humidifying layer disposed in such a state where it is aligned along an aeration surface of a vertical air conditioner is provided with a downstream side guiding means for guiding in downstream direction liquid toward an opposite side of the heat exchanger disposed side. CONSTITUTION:For example, an indoor heat exchangers 5 of upright type is disposed at an indoor heat exchanging part 7 of a package-type air conditioner 2 in an inclined state. A humidifier 1 is installed at a downstream side of aeration flow and humidifying water is dripped and supplied from above. A humidifying layer 22 is formed so that porous ceramic corrugated plates are of short plate extending along a vertical direction and arranged to have curved projects along its vertical direction. Some spacers are present between the adjoining corrugated plates and arranged in side-by-side relation in a lateral width direction. Although aeration holes 22a are formed along an advancing direction of the indoor air supplying between the adjoining curved projections of the porous corrugated plates, they are formed in such a state in which their inclination degrees are more downwardly as they are spaced apart from the heat exchanger. Humidifying water is prevented from flowing out toward the heat exchanger and this is constructed as a downstream side guiding means for guiding it to the side opposite to the place where the heat exchanger exist.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention is used, for example, to control the humidity of a heat exchange gas that is supplied into a room during heating. The present invention also relates to a humidifying device in which a humidifying layer that becomes moist due to a humidifying liquid flowing from a liquid supply device is arranged along a ventilation surface of a heat exchanger in an upright position.

[Conventional technology]

Some humidifiers use a spray or ultrasonic waves to spray humidifying liquid onto the temperature-controlled air that exits the heat exchanger, but in this case, the spray liquid may come into contact with the heat exchanger. However, the heat exchanger had to be subjected to strict anti-caking treatment, which increased production costs.

Therefore, conventionally, a structure has been adopted in which the humidifying liquid is caused to flow down (drop) from the liquid supply device to the humidifying layer, thereby suppressing the scattering of the humidifying liquid compared to the case where it is sprayed. As shown, the humidifier is placed on the lower side of the vertical heat exchanger (5) in the heat exchange gas passage direction, and the humidifying layer (22) of the humidifier is provided with a humidifying layer that slopes downward toward the heat exchanger. A ventilation hole (22a) was formed.

Incidentally, the illustrated humidifying layer (22) is constructed by arranging rectangular porous corrugated plates made of ceramic. In detail, as shown in Figure 2, the porous corrugated plate is
The corrugated sheets are formed in a rectangular shape that extends in the vertical direction and have protruding portions lined up in the vertical direction, and such corrugated sheets are arranged side by side in the width direction with spacers interposed between adjacent corrugated sheets. There is. Therefore, the ventilation hole (22a) is formed between adjacent protrusions. In addition, the spacer is
It is a porous material and is often formed in the shape of a corrugated plate with protrusions lined up in the front-rear direction.

[Problem to be solved by the invention]

Therefore, the humidifying liquid accumulated in the vent holes during humidification flows out toward the heat exchanger when the air blowing is stopped, so that the problem of the humidifying liquid being applied to the heat exchanger cannot be completely solved.

However, as shown in FIG. 7, even if the vent is set in a downwardly inclined position toward the heat exchanger, the liquid supply mechanism is first stopped in response to an operation stop command, and It is also possible to adopt a control form in which the air blowing by the air blowing means is stopped after a predetermined period of time has elapsed, but since the ventilation holes are inclined downward toward the heat exchanger side, it is not possible to completely block the air blowing from the air blowing means. It was not possible to control the outflow, and it required a long time for air to be completely drained, which was not a practical method of operation.

An object of the present invention is to rationally set the flow direction of humidifying water in a humidifying layer to suppress the influence of humidifying water on a heat exchanger.

[Means to solve the problem]

A first characteristic configuration of the humidifying device according to the present invention is a flow guide means for guiding the liquid to flow down into the humidifying layer to the side opposite to the heat exchanger side in order to prevent the liquid from flowing out to the heat exchanger side. The functions and effects are as follows.

[For production]

That is, by forming the downstream guide means, the humidifying water that has flowed down into the humidifying layer passes through the humidifying layer, and as shown in FIG. (22a) and flows out to the opposite side of the heat exchanger (5).

〔Effect of the invention〕

Therefore, by forming the flow guide means to guide the humidifying liquid to the side opposite to the heat exchanger, the humidifying water can flow out to the heat exchanger side without considering the stop timing of the blower means. can be prevented.

As a result, there is no need to apply anti-corrosion treatment to the heat exchanger, or a simple anti-rust treatment is sufficient, which is advantageous in terms of manufacturing cost compared to the conventional configuration, and the above-mentioned flow guide means is not required. It has come to have the advantage that it only requires a simple modification.

The second characteristic configuration described below specifies a preferred specific configuration for implementing the first characteristic configuration, and includes a blowing means for blowing heat exchange gas, and The present invention is further provided with a control means for stopping the liquid supply device and stopping the blowing means after a predetermined period of time has elapsed, and its effects are as follows.

[Action/Effect]

By delaying the stop timing of the air blower by a predetermined period of time from the stop timing of the liquid supply mechanism, it is possible to of course prevent humidifying water from flowing out to the heat exchanger side, and also prevent humidifying water from adhering to the inner surface of the air conditioner case housing the heat exchanger, for example. It also has the advantage of being able to disperse droplets and maintain a dry state.

〔Example〕

Embodiments of the present invention will be described below based on the drawings.

The example diagram shows a humidifier (1) and a packaged air conditioner (2).
As shown in FIG. 3, the package air conditioner (2) is equipped with an outdoor heat exchanger (
3), an indoor heat exchanger (7) that houses an indoor heat exchanger (5), a compressor (6), and an expansion valve (not shown). , the air duct HE (8) located between the sudden exchange R (4) and (7).
), and the above-mentioned Gadan exchange part (4), (7)
and said ventilation duct)! (8) are arranged side by side in close contact with each other.

A fan (9) for outside air intake is installed in the ventilation duct B (8).
and an outdoor duct part (10) connected to the outdoor heat exchange part (4) below the outdoor heat exchange part (4).
), and an outdoor heat exchange section (4).
The structure is such that the heat exchange gas introduced into the outdoor heat exchange section (4) is discharged to the outside by an outside air discharge fan (11) located above the outdoor heat exchange section (4). On the other hand, an indoor return air duct section (12) is provided on the side of the outdoor duct section (10) in the ventilation duct (8), and the indoor return air duct (HE section) (12) is for indoor use. It is configured to send the indoor return air taken in by the indoor return air intake fan (13) provided above the return air duct part (12) to the indoor heat exchange part (7), and is An indoor air supply fan (14) provided at the top of the section (7) is configured to send indoor air supply to each air conditioned room (not shown).

A part of the outside air is mixed into the indoor return air by adjusting a first damper (15) provided below the outside air intake fan (9), and the indoor return air intake fan Second damper (16) provided below (13)
By adjusting a part of the indoor return air to the outside air, it is possible to adjust the state quantities (temperature, humidity) of the heat exchange gas.

A pre-filter (17) and a medium-performance filter (18) are installed at the indoor return air intake in the indoor heat exchange section (7), and these filters (17).

The indoor heat exchanger (5) in an upright position and tilted upward is disposed on the downstream side of the outdoor return air of (18), and the humidifier (1) is installed on the ventilation downstream side of the indoor heat exchanger (5). is equipped with
Furthermore, an eliminator (20) is provided to prevent humidifying water droplets from flowing into the air conditioned room.

Next, the humidifying device (1) will be explained.

As shown in FIG. 2, the humidifying device (19) includes a liquid supply device (21) that supplies humidifying water, and a vent hole (22a).
a humidifying layer (22) which has a
) and a frame (23) that is attached to and supported by the indoor heat exchanger (5), and the humidifying layer (22) is provided with a frame (23) that supports the indoor heat exchanger (5). It is placed along the surface.

The liquid supply device (21) includes a header pipe (21a) that is located above the humidification layer (22) and supplies humidification water, and a valve mechanism (21b) that controls the supply of humidification water to the header pipe (21a). and the humidifying layer (22).
Humidifying water is supplied dropwise from above.

The humidifying layer (22) is constructed by arranging rectangular porous corrugated plates made of ceramic, and more specifically, the porous corrugated plates are rectangular in the vertical direction, and in the vertical direction. The corrugated plates are formed so that the protruding portions are lined up, and such corrugated plates are arranged side by side in the width direction with spacers interposed between adjacent corrugated plates. Then, the humidifying water becomes wet and humidifies the indoor air supply. The humidifying layer (22) also has ventilation holes (22) extending along the direction of movement of the indoor air supply between adjacent protrusions of the porous corrugated plate.
a) will be formed, this vent hole (22a)
As shown in FIG.
The humidifying water is configured as a flow guide means that prevents the humidifying water flowing out to the heat exchanger side and guides the humidifying water downward to the side opposite to the side where the heat exchanger is present. therefore,
It is possible to prevent humidifying water from flowing out to the heat exchanger side and causing the heat exchanger (5) to rust due to moisture.

The frame (23) that supports the humidifying layer (22) is
As shown in Fig. 2, a circumferential frame (23A) that supports the humidifying layer (22), and a circumferential frame (23A) that supports the humidifying layer (22).
Left and right side plates (23B) and (23C) that extend further
And, furthermore, there are vertical bars (
23a) It consists of. The circumferential frame (23
Since only the vertical bar (23a) is provided as the frame that connects A), it is possible to suppress the humidifying water dripping from the horizontal bar from splashing on the heat exchanger (5), which would occur if a horizontal bar is provided. Humidifying water can be guided to the bottom plate (23C) by the vertical bar (23a). In addition, the bottom plate (23C)
A communication hole (23b) is provided in the bottom plate (23C).
) A water reservoir (24) is provided to guide the humidifying water downward and to stop the water guided below the bottom plate (23C).

As shown in FIG. 3, the eliminator (20) is installed at the flow cross-section of the indoor air supply passage, and is configured to prevent pressure loss from becoming large; however, as shown in FIG.
It may be provided above the humidifying layer (5) where the indoor air supply speed is high and water droplets are likely to scatter because it is close to the indoor air supply fan (14), or as shown in FIG. (5
) A structure may be adopted in which the structure is extended upward in the form of an eave to prevent only the scattering of water droplets.

Next, the timing for stopping the humidifier (19) will be explained. When an operation stop command is issued to the air conditioner (2), (1) the liquid supply mechanism (21) is stopped and a predetermined period of time is left;

- Next, after a predetermined period of time has elapsed, the indoor return air fan (13) and the indoor air supply fan (14) are stopped by a control means (25) including a CPU. . Thereby, the interior of the indoor heat exchange section (7) can be sufficiently dried.

[Another example]

■ As a flow guiding means (22a) for guiding the humidifying water to the side opposite to the heat exchanger (5), a vertical hole (22b) is provided in the middle part of the humidifying layer (5), as shown in Fig. 4. For this hole (22b), a side ventilation hole (22b) is opened from the side wall of the heat exchanger and the side of the side opposite to the side where the heat exchanger is present.
a) is formed in a downwardly inclined state, and the vertical hole (22b
) may be configured to collect the humidifying water through the heat exchanger and suppress the outflow of the humidifying water to the heat exchanger side. The reason why the horizontal holes (22a) on the heat exchanger side and the horizontal holes (22a) on the side opposite to the heat exchanger side are formed with opposite slopes is to increase ventilation resistance and suppress water droplet scattering. It is for the sake of putting it out.

◎ As the humidifying layer (22), compressed short fibers may be used, or a sponge-like material may be used. In this case, the downstream guide means (22a
), a gutter-like flow path may be embedded in the humidifying layer (22) so that the humidifying water flows down to the side opposite to the heat exchanger side. In the above, the ventilation passage, the gutter-like flow passage, etc. are referred to as the flow guide means (22a).

(2) The humidifying device (1) may be installed on the upper side of the ventilation in the heat exchanger (5), and its position is not limited to the lower side of the ventilation.

G The humidifying device (1) may be a single device independent from the air conditioner (2).

(2) The means for blowing the heat exchange gas may be either the indoor return air fan (13) or the indoor air supply fan (14).

6. The timing for stopping the air blowing means (14) is as follows:
If the humidifier (1) has been stopped for a long time, this may be done at the same time as the command to stop the air conditioner (2).

Incidentally, although reference numerals are written in the claims section for convenient comparison with the drawings, the present invention is not limited to the structure shown in the accompanying drawings.

[Brief explanation of the drawing]

Fig. 1 is a partially cutaway side view showing the flow guide means formed in the humidifying layer of the humidifying device, Fig. 2 is an exploded perspective view showing the humidifying device, Fig. 3 is a longitudinal sectional front view showing the air conditioner, and Fig. 4 The figure is a partially cutaway side view showing another embodiment of the flow guide means formed in the humidifying layer of the humidifying device, and FIGS. 5 and 6 are side views each showing another embodiment of eliminator attachment. 7th
The figure is a partially cutaway side view showing a conventional flow guide means formed in a humidifying layer of a humidifying device. (5)... Heat exchanger, (5A)... Ventilation surface, (14)... Ventilation means, (21)...
...liquid supply device, (22) ...humidifying layer, (22a) ...cooling guide means, (25) ...
... Control means.

Claims (1)

[Claims] 1. A humidifying layer (22) that has air permeability and becomes moist due to the humidifying liquid flowing down from the liquid supply device (21),
The humidifying device is arranged along the ventilation surface (5A) of the heat exchanger (5) in an upright position, and the humidifying layer (22) prevents liquid from flowing toward the heat exchanger (5). In order to achieve this, the humidifier is provided with a flow guide means (22a) for guiding the liquid downward on the side opposite to the side where the heat exchanger is present. 2. In the humidifying device according to claim 1, a blowing means (14) for blowing heat exchange gas is provided, and the liquid supply device (21) is stopped in response to an operation stop command, and after a predetermined period of time has elapsed. The humidifying device is provided with a control means (25) that then stops the air blowing means (14).